CN114309671A - Method for processing large-caliber off-axis parabolic part - Google Patents

Abstract

The invention discloses a processing method of a large-caliber off-axis parabolic part, which is applied to a vertical lathe, wherein the vertical lathe is provided with a main shaft, an X-axis moving part and a Z-axis moving part connected with the X-axis moving part, a cutter is arranged on the Z-axis moving part, and the processing method comprises the following steps: step S1, determining the processing position of the workpiece; step S2, converting the Cartesian coordinates of the workpiece into cylindrical coordinates; step S3, setting a program; and step S4, executing a program by the vertical lathe, and controlling the main shaft, the X-axis moving component and the Z-axis moving component to cooperatively move so as to machine a preset paraboloid on the workpiece. The machining method is applied to the vertical lathe with two linear motion shafts and a rotating main shaft with an uncontrollable angle, and can realize the deterministic ultra-precise machining of the large-caliber off-axis parabolic part.

Description

Method for processing large-caliber off-axis parabolic part

Technical Field

The invention relates to the technical field of machining, in particular to a machining method of a large-caliber off-axis paraboloid part.

Background

The off-axis paraboloid is one of free-form surfaces, and the off-axis paraboloid part has wide application prospects in terahertz and infrared bands, and is one of common elements for building terahertz light paths and infrared light paths. The large-caliber off-axis paraboloid part is difficult to manufacture, and needs to be machined by a large lathe in a rotationally symmetrical mode or machined on a medium and small lathe in a non-rotationally symmetrical mode through coaxial installation. The method realizes the manufacture of the large-caliber off-axis paraboloid optical part and has important significance for the modernized development of the national defense science and technology industry fields of aerospace and the like.

At present, the traditional method for manufacturing the large-caliber off-axis paraboloid part is mainly to process a rotationally symmetrical large-caliber primary paraboloid part and then intercept the required off-axis part. On the one hand, the method needs a large machining lathe, and simultaneously causes material waste and increases the manufacturing cost. The current advanced methods for machining off-axis parabolic parts are mainly fast tool servo technology and slow slide servo technology. The fast tool servo technology is suitable for parts with complex shapes and small rise heights, and the slow slide carriage servo technology is suitable for processing workpieces with simple shapes and large rise heights. For the off-axis parabolic part with the large caliber, a suitable processing method is not available due to the large caliber, the complex processing shape and the large rise, so that a processing method of the off-axis parabolic part with the large caliber is urgently needed.

In view of the above, the present invention is particularly proposed.

Disclosure of Invention

The technical problem to be solved by the invention is to overcome the defects of the prior art and provide a method for processing a large-caliber off-axis parabolic part, so that the deterministic ultra-precision processing of the large-caliber off-axis parabolic part can be realized.

In order to achieve the above purpose, the present application provides the following technical solutions:

a processing method of a large-caliber off-axis parabolic part is applied to a vertical lathe, the vertical lathe is provided with a main shaft, an X-axis moving part and a Z-axis moving part connected with the X-axis moving part, a cutter is arranged on the Z-axis moving part, and the processing method comprises the following steps:

step S1, determining the processing position of the workpiece;

step S2, converting the Cartesian coordinates of the workpiece into cylindrical coordinates;

step S3, setting a program;

and step S4, executing a program by the vertical lathe, and controlling the main shaft, the X-axis moving component and the Z-axis moving component to cooperatively move so as to machine a preset paraboloid on the workpiece.

Optionally, step S1 includes:

and determining the position of the workpiece to be machined according to the equation of the paraboloid to be machined and the machining range, performing rotary translation transformation on the workpiece to transfer the center of the workpiece to the origin of coordinates of the lathe, and calculating parameters to be translated and rotated.

Optionally, step S2 includes: defining a machining coordinate system and a machining start position, and converting Cartesian coordinates (x, y) of the workpiece into cylindrical coordinates

And translating the coordinate points to a processing range, inputting the coordinate points into a parabolic equation to calculate a required z value, and performing rotation transformation on the z value according to the rotation matrix to obtain the z value required by the current position.

Optionally, a time-base trigger is set on the spindle, and step S4 includes: and a time base control executive program based on the PMAC realizes the three-axis linkage control of the rotation of the spindle, the precise feed motion of the Z-axis moving component and the X-axis moving component under the condition that the position of the spindle is uncontrollable in cooperation with the time base control of the PMAC.

Optionally, step S4 includes: the vertical lathe controls the motion and the execution rate of the program according to the frequency of the spindle rotation as an input signal.

Optionally, a hall sensor and an encoder are disposed on the spindle, and the frequency according to the rotation of the spindle as an input signal includes: the encoder signal frequency on the main shaft is taken as the frequency of the input signal of the controllable shaft, so that the time base control is always carried out.

Optionally, step S4 includes;

s41, converting the frequency of the spindle encoder signal into a voltage signal, and regarding the voltage signal as the frequency of an input signal;

and S42, calculating the update rate of program execution according to the frequency of the input signal, and controlling the program execution process according to the update rate.

Alternatively, in step S42, the update rate is calculated by the following formula:

where,% value is the update rate, RTIF is the frequency of the input signal, and is calculated by the following formula:

RTIF ═ spindle speed × encoder resolution;

TBSF is a time-based factor and is calculated by the following formula:

alternatively, in step S4, the PMAC is controlled to wait for the base point signal of the encoder to trigger the program, based on the determination of whether the time base is frozen and whether the system has moved to the following zero point.

By adopting the technical scheme, the invention has the following beneficial effects:

the machining method is applied to the vertical lathe with two linear motion shafts and a rotating main shaft with an uncontrollable angle, and can realize the deterministic ultra-precise machining of the large-caliber off-axis parabolic part.

The following describes embodiments of the present invention in further detail with reference to the accompanying drawings.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this application, illustrate embodiment(s) of the invention and together with the description serve to explain the invention without limiting the invention to its proper form. It is obvious that the drawings in the following description are only some embodiments, and that for a person skilled in the art, other drawings can be derived from them without inventive effort. In the drawings:

FIG. 1 shows a general flow chart of a method of machining a large caliber off-axis parabolic part;

FIG. 2 shows a front view of a Nanosys-1000 vertical numerically controlled optical machining lathe;

FIG. 3 is a flow chart of a method for machining a large-caliber off-axis parabolic part;

figure 4 shows a PLC program flow diagram of a method of machining a large diameter off-axis parabolic part;

fig. 5 shows a schematic diagram of coordinate transformation in a machining method of a large-caliber off-axis parabolic part.

In the figure, 1, Z-axis moving parts; 2. an X-axis moving member; 3. a main shaft; 4. a cutter; 5. a time base trigger.

It should be noted that the drawings and the description are not intended to limit the scope of the inventive concept in any way, but to illustrate it by a person skilled in the art with reference to specific embodiments.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and the following embodiments are used for illustrating the present invention and are not intended to limit the scope of the present invention.

In the description of the present invention, it should be noted that the terms "upper", "lower", "inside", "outside", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience in describing the present invention and simplifying the description, but do not indicate or imply that the referred device or assembly must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted" and "connected" are to be interpreted broadly, e.g., as being either fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Referring to fig. 1 to 5, the embodiment of the present application provides a method for processing a large-caliber off-axis parabolic part, which is applied to a vertical lathe, the vertical lathe is provided with a main shaft 3, an X-axis moving part 2 and a Z-axis moving part 1 connected to the X-axis moving part 2, a tool 4 is arranged on the Z-axis moving part 1, the X-axis moving part 2 can translate along an X-axis, and the Z-axis moving part 1 can translate along a Z-axis direction. The main shaft 3 can extend along the Z-axis direction, the top end of the main shaft 3 is provided with a table board, and a workpiece can be clamped on the table board. The processing method comprises the following steps:

step S1, determining the processing position of the workpiece;

step S2, converting the Cartesian coordinates of the workpiece into cylindrical coordinates;

step S3, setting a program;

step S4, the vertical lathe executes a program to control the spindle 3, the X-axis moving part 2 and the Z-axis moving part 1 to move cooperatively, so as to machine a predetermined paraboloid on the workpiece.

In the embodiment, the Cartesian coordinates of the workpiece are converted into the cylindrical coordinates, so that the vertical lathe with the two linear motion axes (the X-axis moving part 2 and the Z-axis moving part 1) and the rotating main shaft 3 with an uncontrollable angle can realize the deterministic ultra-precise machining of the large-caliber off-axis paraboloid part, and the method is simple and easy, convenient and efficient, and low in cost.

The processing method of the large-caliber off-axis parabolic part provided by the invention realizes the processing of the large-caliber off-axis parabolic part by utilizing the lathe platform with two linked shafts, and can be popularized to the processing of other non-rotary symmetrical and irregular free curved surfaces. Illustratively, the lathe can be a Nanosys-1000 vertical numerically controlled optical machining lathe.

Alternatively, referring to fig. 5, step S1 includes: and determining the position of the workpiece to be machined according to the equation of the paraboloid to be machined and the machining range, performing rotary translation transformation on the workpiece to transfer the center of the workpiece to the origin of coordinates of the lathe, and calculating parameters to be translated and rotated. Wherein the origin of the lathe coordinate may be the axis of rotation of the spindle 3.

Referring to fig. 5 and 3, step S2 includes: defining a machining coordinate system and a machining start position, and converting Cartesian coordinates (x, y) of the workpiece into cylindrical coordinates

And translating the coordinate points to a processing range, inputting the coordinate points into a parabolic equation to calculate a required z value, and performing rotation transformation on the z value according to the rotation matrix to obtain the z value required by the current position.

Referring to fig. 4, alternatively, the time base trigger 5 is provided on the spindle 3, and step S4 includes: based on the time base control executive program of the PMAC, realize the main axis 3 rotates under the uncontrollable situation of main axis 3 position in coordination with the time base control of the PMAC, the three-axis coordinated control of the precise feed motion of the Z-axis moving component 1 and the X-axis moving component 2.

The motion program cannot prepare a machining start triggering function, and the machining start triggering is controlled and completed by a PMAC built-in PLC for reliable running of the program. In the PLC program, the PMAC waits for the base point signal of the main encoder to trigger the base program once the time base trigger 5 is ready, conditioned on whether the time base is frozen and whether the system has moved to the following zero.

The time-based control method is a more complex control mode for coordinated control between the controllable axis and the uncontrollable axis, i.e. the frequency of the uncontrollable axis as an input signal is used for controlling the motion and the execution rate of the program. The time base control is made to proceed by designating the uncontrollable axis encoder signal frequency as the input signal frequency for the controllable axis. By using this control method, not only is its speed of motion proportional to the input frequency, but all positions between the uncontrollable and controllable axes can be kept synchronized. The method is characterized in that a Nanosys-1000 numerical control optical processing lathe is used for processing the paraboloid part, and a Z-axis moving part 1 of the lathe follows a rotating main shaft 3 in real time in the processing process to process the required paraboloid.

Further, step S4 includes: the vertical lathe controls the execution rate of the motion and the program according to the frequency of the rotation of the spindle 3 as an input signal.

A hall sensor and an encoder may be provided on the spindle 3, and the frequency according to the rotation of the spindle 3 as an input signal includes: the encoder signal frequency on the spindle 3 is taken as the frequency of the input signal of the controllable shaft, so that the time base control is always performed.

Optionally, step S4 includes;

s41, converting the frequency of the spindle 3 encoder signal into a voltage signal, and regarding the voltage signal as the frequency of an input signal;

in this step, signal decoding is performed, and the external uncontrollable axis encoder signal is frequency-converted into a voltage signal, which is regarded as an external frequency source.

And S42, calculating the update rate of program execution according to the frequency of the input signal, and controlling the program execution process according to the update rate.

Alternatively, in step S42, the update rate is calculated by the following formula:

where,% value is the update rate, RTIF is the frequency of the input signal, and is calculated by the following formula:

RTIF is spindle 3 rpm x encoder resolution. Wherein the rotating speed of the spindle 3 can be obtained by a Hall sensor.

TBSF is a time-based factor and is calculated by the following formula:

taking the rotation speed of the main shaft 3 of 100r/min and the resolution of a shaft encoder of 320000 lines/r as an example: the calculation result shows that RTIF is 533.33cts/ms, for the convenience of calculation, RTIF is 512cts/ms, the corresponding rotating speed is 96r/min, and the time base factor TBSF is 2¹⁴/512＝32。

Alternatively, in step S4, the PMAC is controlled to wait for the base point signal of the encoder to trigger the program, based on the determination of whether the time base is frozen and whether the system has moved to the following zero point.

And writing a motion program and a PLC time base trigger program. In the PLC program, only one conditional branch is needed to judge whether the time base is frozen or not, and the PLC triggers the time base control program to start once the system is ready according to the judgment condition whether the time base is frozen or not as whether the system moves to the starting point or not.

And (3) starting triggering time base control, when the system moves to the starting point and the PLC program triggers the time base control, the main shaft 3 encoder starts capturing the starting signal, and after the signal is acquired, the frequency of the uncontrollable shaft is used for processing, so that three-shaft linkage is realized.

Although the present invention has been described with reference to a preferred embodiment, it should be understood that various changes, substitutions and alterations can be made herein without departing from the spirit and scope of the invention as defined by the appended claims.

Claims (9)

1. A processing method of a large-caliber off-axis parabolic part is applied to a vertical lathe, the vertical lathe is provided with a main shaft, an X-axis moving part and a Z-axis moving part connected with the X-axis moving part, and a cutter is arranged on the Z-axis moving part, and the processing method is characterized by comprising the following steps:

step S1, determining the processing position of the workpiece;

step S2, converting the Cartesian coordinates of the workpiece into cylindrical coordinates;

step S3, setting a program;

and step S4, executing a program by the vertical lathe, and controlling the main shaft, the X-axis moving component and the Z-axis moving component to cooperatively move so as to machine a preset paraboloid on the workpiece.

2. The method for processing a large-caliber off-axis parabolic component according to claim 1, wherein the step S1 comprises:

and determining the position of the workpiece to be machined according to the equation of the paraboloid to be machined and the machining range, performing rotary translation transformation on the workpiece to transfer the center of the workpiece to the origin of coordinates of the lathe, and calculating parameters to be translated and rotated.

3. The method for processing a large-caliber off-axis parabolic component according to claim 1, wherein the step S2 comprises: defining a machining coordinate system and a machining start position, and converting Cartesian coordinates (x, y) of the workpiece into cylindrical coordinates

And translating the coordinate points to a processing range, inputting the coordinate points into a parabolic equation to calculate a required z value, and performing rotation transformation on the z value according to the rotation matrix to obtain the z value required by the current position.

4. The method for processing a large-caliber off-axis parabolic component according to claim 1, wherein a time-based trigger is provided on the main shaft, and the step S4 includes: and a time base control executive program based on the PMAC realizes the three-axis linkage control of the rotation of the spindle, the precise feed motion of the Z-axis moving component and the X-axis moving component under the condition that the position of the spindle is uncontrollable in cooperation with the time base control of the PMAC.

5. The method for processing a large-caliber off-axis parabolic component according to claim 4, wherein the step S4 comprises: the vertical lathe controls the motion and the execution rate of the program according to the frequency of the spindle rotation as an input signal.

6. The method for processing a large-caliber off-axis parabolic component according to claim 5, wherein a Hall sensor and an encoder are provided on the main shaft, and the frequency according to the rotation of the main shaft as an input signal comprises: the encoder signal frequency on the main shaft is taken as the frequency of the input signal of the controllable shaft, so that the time base control is always carried out.

7. The method for machining a large-caliber off-axis parabolic component according to claim 6, wherein the step S4 comprises;

s41, converting the frequency of the spindle encoder signal into a voltage signal, and regarding the voltage signal as the frequency of an input signal;

and S42, calculating the update rate of program execution according to the frequency of the input signal, and controlling the program execution process according to the update rate.

8. The method for processing a large-caliber off-axis parabolic component according to claim 7, wherein the update rate is calculated in step S42 by the following formula:

where,% value is the update rate, RTIF is the frequency of the input signal, and is calculated by the following formula:

RTIF ═ spindle speed × encoder resolution;

TBSF is a time-based factor and is calculated by the following formula:

9. the method as claimed in claim 4, wherein in step S4, the PMAC is controlled to wait for the base point signal of the encoder to trigger the program according to the judgment of whether the time base is frozen and the system has moved to follow the zero point.

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